Method and device for the non-invasive assessment of bones

Abstract

A method for the in vivo non-invasive characterization of the material and architectural properties of a bone in which an ultrasonic wave is introduced into a bone in such way as to produce one or more guided wave modes within the bone, and the signals emerging from the bone are stored and analyzed to determine the propagation characteristics of the guided wave / s. These measured guided wave propagation characteristics are then processed to obtain estimates of desired bone properties such as cortical thickness, bone density and bone elastic constants. The invention also includes an unltrasound arrangement with movable transducers.

Description

FIELD OF THE INVENTION[0001]The invention relates to a method and a device for assessing human bones in vivo using ultrasonic waves. The invention relates to the production and detection of guided ultrasonic waves propagating within a bone, and the determination of bone properties from measured guided wave parameters.BACKGROUND OF THE INVENTION[0002]The so-called axial transmission technique has been used to assess long bones for over four decades (see, for example, Gerlanc et al, Clin. Orthop. Rel. Res. 1975; 111:175-180). With this method, an ultrasonic pulse is transmitted along the long axis of a bone (typically the tibia) from a transmitter to a receiver and the velocity is estimated from the transit time of the first arriving signal and the propagation distance. To account for the effects of overlying soft tissue, either a multiple transmitter / receiver configuration can be used , or transit time can be determined as a function of distance as one transducer is moved relative to...

AI Technical Summary

Benefits of technology

[0007]Another object of the present invention is to provide a method for exciting ultrasonic waves in a bone using low frequency small diameter contact transducers so as to preferentially produce guided waves in the bone. By measuring at low frequencies, the velocity of the first arriving wave has enhanced thickness-dependence, with a velocity tending towards that of the fundamental symmetric Lamb wave. In effect, the first arriving signal can be considered to be a guided wave in these circumstances. Low frequency small diameter transducers behave as approximately point-like transmitters and receivers, radiating energy in all directions, and coupling into additional guided waves that arrive after the first arriving signal.

[0011]Further object of the present invention is to provide a method for employing an array of transducers so that scanning of the receiver can be performed electronically by using different transducer elements, or combinations thereof, as receivers. In this way, the received signal can be measured as function of transmitter-to-receiver distance, and an (r,t) diagram formed as described earlier, but with the advantage that no moving parts are involved.

Problems solved by technology

During in vivo measurements some movement of the patient is to be expected and this may lead to variations in contact force unless corrected for.

Variations in contact force may have an adverse effect on the coupling of acoustic energy into the bone and may lead to errors in the measurements.

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